Three-Dimensional Continuous Conductive Nanostructure for Highly Sensitive and Stretchable Strain Sensor

Cho, Donghwi; Park, Junyong; Kim, Jin; Kim, Tae-Hoon; Kim, Jung Mo; Park, Inkyu; Jeon, Seokwoo

doi:10.1021/acsami.7b03052

Cited by 115 publications

(137 citation statements)

References 59 publications

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“…This has been proven to be difficult 9,20,22,34,35 because large stretching requires structural integrity, whereas substantial changes in the electrically active area are required in order to achieve high sensitivity 36,37 . However, several studies have shown that this is possible with highly sensitive piezoresistive structures 11,13,16,20,34,38,39 , but these sensors often show high contact resistance further limiting their feasibility to wearable sensing. Additional functionalities by fabricating transparent 14,16,19,26,27 , self-healing 40 , self-powered 3,41 , tunable 13,17,19,42 , multidimensional 7,12 and multisensing (strain, pressure, temperature, etc.)…”

Section: Introductionmentioning

confidence: 99%

“…However, several studies have shown that this is possible with highly sensitive piezoresistive structures 11,13,16,20,34,38,39 , but these sensors often show high contact resistance further limiting their feasibility to wearable sensing. Additional functionalities by fabricating transparent 14,16,19,26,27 , self-healing 40 , self-powered 3,41 , tunable 13,17,19,42 , multidimensional 7,12 and multisensing (strain, pressure, temperature, etc.) 3,4,6,10,21,29,32,33,43,44 strain sensors have been investigated.…”

Section: Introductionmentioning

confidence: 99%

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Stretchable and Washable Strain Sensor Based on Cracking Structure for Human Motion Monitoring

Tolvanen

Hannu

Jantunen

2018

Sci Rep

106

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Stretchable and wearable strain sensors have been intensively studied in recent years for applications in human motion monitoring. However, achieving a high-performance strain sensor with high stretchability, ultra-sensitivity, and functionality, such as tunable sensing ranges and sensitivity to various stimuli, has not yet been reported, even though such sensors have great importance for the future applications of wearable electronics. Herein, a novel and versatile strain sensor based on a cracking (silver ink patterned silicone elastomer)-(silver plated nylon structure) (Ag-DS/CF) has been designed and fabricated. The unique structure combined precisely shaped stretchable conductive fabrics and wrinkled Ag-ink pattern to achieve an excellent electrical performance. The Ag-DS/CF could be used to detect both large and subtle human motions and activities, pressure changes, and physical vibrations by achieving high stretchability up to 75%, ultrahigh sensitivity (gauge factor >104–106), tunable sensing ranges (from 7 to 75%). Excellent durability was demonstrated for human motion monitoring with machine washability. The extremely versatile Ag-DS/CF showed outstanding potential for the future of wearable electronics in real-time monitoring of human health, sports performance, etc.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Stretchable and Washable Strain Sensor Based on Cracking Structure for Human Motion Monitoring

Tolvanen

Hannu

Jantunen

2018

Sci Rep

106

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“…[ 7–9 ] On the basis of different mechanisms, flexible strain sensors can be divided into several types including piezoresistivity, capacity, and piezoelectricity. [ 10–14 ] The piezoresistive strain sensors are unquestionably promising candidates for wearable and real‐time human motion‐detecting devices, [ 15,16 ] and they can be sensitive enough for even 10 nm vibration, [ 17 ] but the piezoelectric sensors are more prospective for self‐powered devices owing to the piezoelectric effect of materials, defined as the occurrence of polarization when the material is subjected to external stress as a result of the separation of the positive and negative gravity centers of the molecules. Lead zirconate titanate (PZT) and polyvinylidene fluoride (PVDF) are the most commonly used piezoelectric mediums for piezoelectric sensors due to their high piezoelectric coefficients ( d 33 ).…”

Section: Introductionmentioning

confidence: 99%

Wearable and Ultrasensitive Strain Sensor Based on High‐Quality GaN pn Junction Microwire Arrays

Cheng

Han

Cao

et al. 2020

Small

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With the rapid growth in wearable electronics sensing devices, flexible sensing devices that monitor the human body have shown great promise in personalized healthcare. In the study, high-quality GaN pn junction microwire arrays with different aspect ratios and large-area uniformity are fabricated through an easy, repeatable fabrication process. The piezoelectric coefficient (d 33 ) of GaN pn junction microwire arrays increases from 7.23 to 14.46 pm V −1 with the increasing of the aspect ratio, which is several times higher than that of GaN bulk material. Furthermore, flexible ultrasensitive strain sensor based on GaN microwires with the highest d 33 is demonstrated to achieve the maximum open circuit voltage of 10.4 V, and presents excellent durability with stable output signals over 10 000 cycles with a response time of 50 ms. As a flexible and wearable sensor attached to the human skin, the GaN microwire pn junction arrays with such a high degree of uniformity can precisely monitor subtle human pulse and motions, which show great promise in future personalized healthcare.The piezoresistive strain sensors are unquestionably promising candidates for wearable and real-time human motiondetecting devices, [15,16] and they can be sensitive enough for even 10 nm vibration, [17] but the piezoelectric sensors are more prospective for self-powered devices owing to the piezoelectric effect of materials, defined as the occurrence of polarization when the material is subjected to external stress as a result of the separation of the positive and negative gravity centers of the molecules. Lead zirconate titanate (PZT) and polyvinylidene fluoride (PVDF) are the most commonly used piezoelectric mediums for piezoelectric sensors due to their high piezoelectric coefficients (d 33 ). [18][19][20][21] However, the toxic lead component in PZT and the high impedance of PVDF have limited their applications in wearable piezoelectric devices. [22,23] In this regard, semiconductor-based piezoelectric strain sensors represented by zinc oxide (ZnO) and GaN have been extensively studied as a result of their mechanical and chemical stability as well as environmental and biological compatibility. [24][25][26][27][28] In addition to the above advantages of the semiconductor, GaN exhibits merits of easy control of carrier concentration doping and higher stability compared to ZnO, while internal free carriers reduce the output of the device by screening the piezoelectric polarization, which is called free carriers screening. Suppressing the free carriers screening is undoubtedly an effective approach to improve the piezoelectric performance of the devices. [27,29,30] Another method is replacing the bulk or film materials with nanowires (NWs) considering the superior mechanical properties, large aspect ratio, and high energy conversion efficiency of NWs as compared to bulk materials. [31][32][33][34][35] For instance, Kacimi et al. fabricated a flexible strain sensor exhibiting 2 V peak outputs with vertically aligned ultra-long GaN wires, [36] ...

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“…Since conventional magnetic particle testing (MT), penetrant testing (PT), and ultrasonic testing (UT) methods are difficult for precise large‐scale infrastructure diagnosis, many techniques were proposed on this topic in recent years, such as sensing techniques of electrical resistance or capacitive MEMS strain sensors and piezoelectric sensors were proposed for precise strain or anomaly detection, but these methods still had limitations for strain imaging on real world structures due to the sensor scale and/or spatial resolution . On the other hand, new types of sensors based on photoelectric methods such as assembled nanowires/nanotubes or microstructured rubber layers, stretchable and flexible strain sensor with conductive nanostructure for sensitive detection of human motion, piezotronic/piezo‐phototronic‐effect enhanced light emitting smart sensors, and flexible or bionic mechanosensors were proposed as effective sensing techniques for dynamic imaging of pressure or stress and diagnosing movement disorders in high‐resolution . However, fabrication methods of the abovementioned nanowire array or flexible smart sensors are complicated, and they are inconvenient for scalable precise stress/strain imaging and especially difficult for large‐scale application and onsite real world infrastructures.…”

Section: Introductionmentioning

confidence: 99%

Scalable Elasticoluminescent Strain Sensor for Precise Dynamic Stress Imaging and Onsite Infrastructure Diagnosis

Liu

Yoshida

et al. 2018

Adv Materials Technologies

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structures attracted world-wide attention in order to ensure effective maintenance and avoid recurrence of such severe disasters. [1][2][3] In December 2017, a serious incident happened at a Shinkansen bullet train of Japan due to anomalous load caused fatigue cracks and rupture in an undercarriage, [4] and this sudden incident further enhanced the urgent necessity to predict the fracture (damage) of infrastructures. Since conventional magnetic particle testing (MT), penetrant testing (PT), and ultrasonic testing (UT) methods are difficult for precise largescale infrastructure diagnosis, many techniques were proposed on this topic in recent years, such as sensing techniques of electrical resistance or capacitive MEMS strain sensors and piezoelectric sensors were proposed for precise strain or anomaly detection, but these methods still had limitations for strain imaging on real world structures due to the sensor scale and/or spatial resolution. [5][6][7][8] On the other hand, new types of sensors based on photoelectric methods such as assembled nanowires/nanotubes or microstructured rubber layers, [9][10][11][12][13][14][15] stretchable and flexible strain sensor with conductive nanostructure for sensitive detection of human motion, [16] piezotronic/piezo-phototronic-effect enhanced light emitting smart sensors, [17,18] and flexible or bionic mechanosensors were proposed as effective sensing techniques for dynamic imaging of pressure or stress and diagnosing movement disorders in high-resolution. [19][20][21][22][23] However, fabrication methods of the abovementioned nanowire array or flexible smart sensors are complicated, and they are inconvenient for scalable precise stress/strain imaging and especially difficult for large-scale application and onsite real world infrastructures.Herein, we report another mechanism of largely scalable and flexible strain sensor using elasticoluminescent smart paint for challenge to solve worldwide structural diagnosis problems ranging from micro to macroscales. The elasticoluminescence presented in this study also called elastico-mechanoluminescence is a unique form of mechanoluminescence (ML) that can generate repeatable and reproducible light emission during elastic deformation. [24][25][26][27][28][29] The new scalable elasticoluminescent strain sensor has great significance on high sensitivity and precise dynamic stress/strain imaging, and onsite fracture inspection and diagnoses on large-scale infrastructures. The innovative scalable strain sensor would prospectively open a Precise dynamic stress/strain imaging is critical for a broad range of research and engineering analyses ranging from micrometer to meter-scales, but there is no precise multiscale strain sensor, especially for onsite real-time structural health monitoring. Here, a scalable elasticoluminescent strain sensor is presented for solving worldwide structural diagnosis problems ranging from micrometer to meter-scales. Significant progress has recently been made on both highly sensitive elasticoluminescent sensor...

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Three-Dimensional Continuous Conductive Nanostructure for Highly Sensitive and Stretchable Strain Sensor

Cited by 115 publications

References 59 publications

Stretchable and Washable Strain Sensor Based on Cracking Structure for Human Motion Monitoring

Stretchable and Washable Strain Sensor Based on Cracking Structure for Human Motion Monitoring

Wearable and Ultrasensitive Strain Sensor Based on High‐Quality GaN pn Junction Microwire Arrays

Scalable Elasticoluminescent Strain Sensor for Precise Dynamic Stress Imaging and Onsite Infrastructure Diagnosis

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